Motor-controller.



No. 654,883. Patented my 3|, |900. w. B. ELLIOTT & J. w. EsKHoLME.

MOTUR CONTROLLER.

(Application led Apr. 2, 1900.)

5 Sheets-Sheet l,

(No Model.)

IIJ

.d Ji. nJ.

WITNESSES:

' ATTORNEY No. 654,383. Patented my 3|, |900. w. B. ELLIOTT & J. w. EsKHoLME.

MOTDR GDNvTROLLER. (Application med Apr. 2, 1900.)

5 Sheets-Sheet 2 (No Model.) v

m@ ME. .m W. W

ATTORNEY No. 654,883. Patented my 3|, |900;

. w. B. ELLIOTT L J. w. 'EsKHoLm-L MOTOR CONTROLLER.

(Application med Apr. 2 1900.) (No Model.) l y5 Sheets-Sheet 3,

I,Illu

ATTORNEY TH: Nonms Pneus cov. PHoTauTHo., wAsmNuToN. o, c.

No. 654,883. Patented .luly 3|, |900.

v W. B. ELLIOTT & J. W. ESKHOLME.

MOTOR GUNTROLLEH.

` (Application filed Apr. 2, 1900.) (N0 MOdHL) 5 Sheets-Sheet 4,

ATTORNEY Tn: Noams 'vrrsns co.. mom-uma., wAsmnsroN, n. c.

Patented July 3|, |900. W. B, ELLIOTT &. J. W. ESKHOLME.

MOTOR CONTROLLER.

(Application tiled Alu. 2, 1900.)

- 5 Sheets-Sheet 5,

(No Model.)

1H: mams PETERS cn., PHDTQLITND.. wAsmNG-rou. Dy c.

Nien i TATES PAfrEIvrv rtree.

WILLIAM BnEwsrEn .ELLIOTT ANIo'JOI-IN WILLIAM ESKIIOLMEOE 'wEsr- FIELD, NEw .IEEsEY, AssIeNoRs To rrI-IE C. a c. ELECTRIC COMPANY;

OF NEW JERSEY.

Moron-CONTROLLR;

SPECIFICATION forming part of Letters Eatent No. ceases, date .J'uiy'l 31, Ieoo. Application tiled April 2,1900. Serial No. 11,037. (No model.)

To @ZZ wit-m 2 may concern.-

Be it known that we, WILLIAM EEEWsTER ELLIOTT and JOHN WILLIAM EsKIioLME, citizens of the United States, residing at Westiield, New Jersey, have invented certain new and useful Improvements in Motor-Controllers, of which the following isva'full, clear, and exact description.

Our invention relates toa new and improved apparatus for controlling the speed of, preferably, a motor having a plurality of independent windings; and one of our objects is to provide a device whereby this motor may be started at an extremely-slow speed having great torque and the speed gradually increased as desired, preferably by means of a single hand-lever.

Our invention is particularly applicable for use with printing-presses which are driven by an electromotor directly connected or geared to the press. One difficulty heretofore experienced in the operation of large printingpresses particularly by such av motor has been due to the diflicultyof obtaining a slow enough and at the same time a steady motion to enable the pressman to properly feed 'the paper through the rolls at starting and of increasing the speed to the full desired speed without any jerks. Should jerks occur in 3o starting the motor or in changing the speed, the paper which is running through the press would be extremely liable to be broken, entailingconsiderable loss ot' time and expense. By our construction we have avoided these objections, and in the embodiment shown in the drawings a single hand-lever is provided, by the movementl of which'in one direction the Inotor may be started at any speed desired and this speed be gradually and steadily increased without any jerks to full speed by a continued movement of the lever in the same direction. By a reverse movement of the lever the motor may be gradually and steadily slowed down. The hand -lever is preferably located close to lthe press, and one pressman can therefore :completely control the running of the press by a simple movement of this one lever in one direction or the other and at the same time attend to other 5o duties, such as adjusting the tension on the paper-roll. The connection from this lever few enough turns to prevent sparking at full mechanical or electrical.

In using a motor or motors with printingl presses if there are enough turns in the armature winding to produce the necessary torque at starting the motor will probably spark when rotating at its full speed, and, on the other hand, if the armature is used with to the parts controlled by it may be either 6o speed the current necessary to start the rota= tion of the armature must be comparatively great, as the torque depends on the ampereturns on the armature. To overcome this objection, we have preferably provided what we have 'called herein a plurality of armature-windings and means for controlling these windings. This motor in this embodiment is made up of two separate armaturewindings and commutators mounted on the 7o same core and shaft; but we do not desire to be limited to lthis construction, as we are aware that two independently-rotatable windings could be used, such as two independent motor-armatures, and yet the windings be connected the same as in the present method of control, and we use the word motor77 with this broad meaning. If these windings are connected in series when the machine is started, sufficient ampere-turns will be provided to start the machine without a great amount of current, and if the windings are thrown from series into parallel before the machine reaches its full speed, preferably at half-speed, there will be no sparking at the commutators at full speed, as there otherwise would be.

In the preferred embodiment of our invention shown in the drawings, Figure l is a diagram of the connections. Fig. 2 is a side elevation of part of thejprinting-press, showing the hand-lever, two of the switches in the main circuit, the terminal arc, and the controlling-lever contacting'with these terminals. Fig. 3 shows more detailed view of thecontrolling-lever and connections thereto. Fig. 4: is a side elevation of Fig. 3. Fig. 5 is adetailed view of the terminal arc, the stationary contact-strips, and the Controlling-lever. Fig. 6 is a detailed view of the spring-contacts on the main switches. Fig. 7 is an en- IOO larged view ofthe switch lever and blades in the armature-circuit. Fig. 8 is a detail show'- l ing the method of mounting and insulating the switch-blades in these main switches. Fig. 9 is a detailed view of the magnets and other parts for actuating` the main switches. Fig. l0 is a diagrammatic view showing the two armature-windings and commntators on the same shaft.

In the above preferred embodiment of our invention we have provided a pair of armature-windings on the same core and shat't, each of which windings is provided with a separate comm utator on said shaft and a multipolar shunt or compound-wound field-magnet surrounding these two windings. To control this motor, we have provided different connections and resistances, and preferably a single controlling-lever, to make the different connections. XVe have preferably ar ranged the terminals in the form of a circle or the are of a circle, as seen in Fig. 5, and pivoted in the center the controlling-lever, (shown in detail in Figs. 3 and 4,) and have connected this controlling-lever with a handlever, so that by the movement of the handlever in one direction one switch in the armature-circuit is thrown to close the circuit through. the windings, which should then be in series. if the windings are then in parallel, a switch will be thrown at the same time and connect them in series. By a further movement of the hand-lever in the same direction a series of rcsistances are in succession cut out of the arm aturecircuit. The field may be weakened, preferably, by short-circuiting a part of the series compounding, the series compounding being ef high-resistance material when cut out also decreases the resistance in series with the armature-windings, and by a further movement of the handlever in the same direction the armatures are thrown into parallel and at the same time a substantially compensating resistance is introduced into the armature-circuit, and by a further Aforward movement of the hand-lever some of this resistance is cut out. XVe have also provided a series of resistances in the shunt-field windi1ig,\vliich may be introd ueed by a further movement of the hand-lever in the same direction to further weaken the field and still further increase the speed of the motor. By a reverse movement of the hand-lever these shunt-field resistances are successively cut out. Then a series ofresistances are introduced into the armature-circuit, and on a further backward movement of the hand-lever the armature-circuit is opened, and in this embodiment the windings are thrown from parallel into series, preferably at the same time.

As seen in Fig. 2, l represents the printing-press; l, the paper-feed roll; 2, the floor on which the printing-press is mounted; 3, the motor in outline7 and at a gear carried by the armature-shaft engaging with a gear 5, which drives the press. t7 and 4S are two switches in the main circuit. 8 is a teimnal are which is passed over by the preferably-pivoted sliding controlling-lever 9 to automatically make different connections. l() is a toothed. wheel carried by the shaft upon which the lever 9 is mounted, and ll is a toothed segment engaging with the wheel lO and pivoted at lin. l2 is the hand-lever, pivoted at 13 and having` a safety-catch 1i engaging a stationary toothed segment llt. The lower arm l5 of the handlever is connected with the toothed segment ll by a link 16. All the parts of the mechanism, except the hand-lever 12 and toothed segment lt, are preferably below the floor, thus being out or" the way and allowing the pressman to control the press merely by moving the handlever in one direction or the other.

Referring to Figs. 3l and 4;, which show dctails of the controlling-lever 9 and other parts connected therewith, the controlling-lever 9 is fixed to the shaft l0, which is rotatable in a suitable frame i8 and carries contactblocks lt), 20, 2l, and 1.3. The contact-block 19 contacts with and makes electrical connection between the terminals 2t 25 2G f3" and 2S 20. (See 5.) The block 2O contacts with and bridges the terminal blocks of the are S, which are insulated from each other, with the exception of suitable resistance-coils. Block 2l bridges the stationary terminal strips 30 and 3l and block 23 contacts with circular terminal strip .32. 33, Fig. i, is a counterweight on this controlling-lever. Fixed to the shaft lO is a second lever 3ft, which is attached at one end by the connection 35 to the lever 9 and at the other end carries a pin 3G, which engages with the 'forked end of a contact-switch 37, which passes across and bridges contact-points 38 and 30 on the frame 1S. As the lever 0, Fig. 5, rotates from left to right it strikes a pin 40 on a metallic switch portion fil, carried by a spring 42, and pushes the same to the right. On the return of the lever from right to left the end of the lever strikes the pin t0 on the opposite side and pushes said contact portion 4l to the left into engagement with the other switch-terminal 43.

The diagram shown in Fig. l is laid out as though the contact segments and rings shown in Fig. 5 had been bent up into parallel straight lines. The current enters by the main -iit and passes up through the switchblade t5 ot' the three-pole switch i6, which will be hereinafter described, from thence through an overload switch to one terminal of the main switch t7. This switch is shown in diagram in the open position by dotted lines and in its closed position by full lines. The controlling-lever i) is shown as moved from its position of rest in Fig. 5 a short distance toward theright until it touches the contact-points 2U and 27.

To throw the main switches i7 and i8, Fig. l, we have provided two pairs of electromagnets preferablyin the vform of solenoids,which are energized when the lever 9 bridges cer- IOO IIO

' lines and oppositely situated.

tain contact-points. In this embodiment we have provided a device to open the circuit through the solenoid which has thrown the switch 47 or 48) as soon as the switch-blade leaves its terminal. Details of the main switches 47 and 48 are shown in Figs. 6, 7, and 8. To provide a reliable contact for the switchblade 49, we have provided, preferably, a pair of contact-springs, Fig. 6, made of spring-copper, and these springs preferably consist of a main portion 50 50, suitably fixed to a post or standard 5l, the ends 52 52 of which are turned over upon the main portion and lie between the main portion 50 50 and are engaged by the switch-blade when thrust therein. In this way we have provided a contact part which has a double, spring. The outer or main portion of the contact-spring will be forced outwardly, and if these were all the spring-jaws that were provided the main blade when it entered between the jaws would not contact with the same for the entire length of the jaws, as the same would be bent outward and form a sort of V-shaped opening. In the present construction, however, although the outer portion 50 of the jaws may be bent outward slightly, the inner or turnedover portion 52 can springin the opposite direction, because it is slightly separated from the main portion, and thus make a sure contact with the entire portion of the switchblade which has entered between the jaws.

The switch-blades 49 are preferably insulated from the switch-lever 47 48. of a blade is shown in Fig. 8. The switchlever 47 (48) carries at the end a pin 53, which pin enters a hole in the blade, and this pin is surrounded by an insulation-cushion 54. One end of the lever is attached toan insulated cushion 55 to steady the same. It will be obvious that if the switch-blade 49 directly contacted with the cushion or insulation 54 the repeated blows which the edges of the aperture in the blade would give the cushion 54 would soon cut through the same and prob-- ably ground the circuit on the pin 53. To protect this insulation and to distribute the force of the blow over a considerable surface of the same, we have provided a sleeve 56, preferably made of brass, which may surround this insulation 54. 57 is a further insulating-cushion to hold the blade 49 in place, but allowing slight movement of the same to accommodate itself to the spring-jaws.

One of the pair of magnets-in this case solenoids-which we have provided to throw the switches 47 and 48 is shown in detail in Fig. 9 and in outline in Fig. 7. The switches 47 and 48 are preferably mounted on slateboards 58, and on the back of these boards (see Fig. 7) are mounted the solenoids 59 and 60. These solenoids are preferably ironclad to form a more complete path for the magnetic The shaft 6l, upon which the lever 47 (48) is mounted,passes through the board 58 and carries on the inner end thereof a second lever 62, and the lower A detail- CIC)` end of this lever 62 carries a pin 63. 64 is a core for the solenoids,which we may designate an armature for the magnet formed by the solenoid. It will be obvious that to throw the switch 47 more power will be required at the first part of this movement than at the last, because the switch-blade 49 must be pulled out of the contact-jaws. The solenoid, however, operates with the least effect on the core at the beginning. To increase this initial pull on the core, we have therefore provided an auxiliary core, preferably movable, to increase the number of magnetic lines, which auxiliary core is intended to normally stand at a slight distance from the end of the core 64, as shown in dotted lines at the left in Fig. 9. Then the solenoid is energized, the auxiliary core therein will be drawn inward toward the right and will increase the number of magnetic lines within the solenoid, and as the space between the end of the auxiliary core and the end of the core 64 is comparatively slight the solenoid will operate with increased lforce upon the core 64 and draw the same quickly to the left. The auxiliary core, however, being movable, is pushed out of the way by core 64, thus allowing core 64 t-o traverse its full distance.

To provide an additional aid to the mere strength of the solenoid in pulling out the switch-blade 49 from the contact-jaws, we have provided means to strike a quick hammer-blow against the pin 63, andthus insure a quick movement of the switch-lever. Io accomplish this object, we have provided an abutment on the core 64 which shall strike the pin 63, which pin is connected through lever 62 and shaft 6l with the movable switchlever 47, and in this embodiment of our invention this abutment is formed by the end of a slot 65 in the core into which the pin 63 passes. It will be obvious that if the solenoid 60 is energized the core 64 will be quickly drawn to the left, and the end of the slot 65 coming in contact with the pin 63 will suddenly strike the lever 62, and consequently jerk switch-lever 47 over into its opposite position. It is not necessary that the solenoid should act with a pull upon the switch-lever 47 after the blade 49 'has left the contact-jaws, because the momentum of thfe lever 47 will then be sufficient to carry it across and into the opposite pairs of contact-jaws. We therefore have provided a means to automatically open the closed solenoid-circuit on the movement -of the core.

66 is a stationary contact-block, preferably made of carbon, which forms one terminal of the electric circuits for energizing the solenoids. This circuit, as shown in diagram in Fig. l, may bea shunt from the main circuit.

67 and 68 are pivoted metallic switch-arms provided with springs 69 70, tending to push the arms toward the contact-block 66. Each of these switch -arms may carry a carbon block 7l 72, which contacts with the block The ends of the arms 67 68 Stand in the ICC IIO

path of pins on the end of the lever G2, so that on the movement of this lever suilicient to carry the blades /ll out of the contactjaws one arm or the other will be moved away from the block G6. The arm 67 forms part of a circuit from the block G6 through the solenoid 59, so that when said arm is moved away from the block G6 the circuit through this solenoid is broken. The contact-block on the arm G7 then comes in contact with the block G6; but although this arm (S7 is electrically connected with said shunteircnit through the solenoid (50, as shown in Fig. l, said solenoid (SO is not immediately energized, as will be explained hereinafter.

lVhen we speak of a pair7 of electric circuits, we do not mean necessarily that there must be separate wires for the two circuits, because we consider that in some cases if a current should be sent through a translating device, such as a solenoid, in one direction it would constitute one circuit, and if then the current was reversed the same might act as and give the results of another circuit, and when we say that a circuit includes as a part thereof one of the solenoids we do not mean that both may not be included in it.

To allow a considerable movement of the long core and yet to leave only a comparatively-short space between the ends of it and the auxiliary core, we have in the embodimentillustrated made the auxiliary core just long enough, so that when the arm G7 (or GS) has broken contact with block G6 the end of the long core will strike the movable core. As the auxiliary core is movable, it will be pushed from its position and will thus destroy some of the inertia of the long core and tend to bring it to a standstill. By this arrangement we provide for a very slight clearance between the ends of the two cores (thus strengthening the initial pull on the long core more than would be the case with a greater clearance between the cores) and yet allow a greater movement of the long core than would be possible if the auxiliary core were stationary. This is the preferable construction; but of course the auxiliary core might be stationary.

Referring now to Figs. l and 5, it will be seen that when the lever 9 is moved from its position shown in Fig. 5 to the position shown in Fig. l, in which the block 19 bridges the solenoid-terminals 2G 27, a circuit will then be closed through the arm then in contact with said block 66, as shown in Fig. l in dotted lines at the left of said block, down through the solenoid at the right o1 the lever 47 to the contact-terminal 2G, Fig. 5, through the contact-block 19 on the lever 9 to terminal 27, and from there, as shown in Fig. l, back to the main circuit. This will energize solenoid 50, throwing the lever 47 from the open position shown in Fig. 7 and in dotted lines, Fig. l, to the closed position shown in full lines in said Fig. 1. rlhe current from the main will then pass through the blade 49 at the lower end of the lever t7 over to one of the contact-jaws at the upper end of the lever i8, to and through one armature-winding, through the contact-blade at the lower end oi' the lever 4S, to and through the other armature-winding, from thence to one ofthe contact-jaws at the upper end of the lever 4S, through the blade at the upper end of said lever down to the terminal A, thence through aresistance-coilto the next contact-block, and from there through the series compounding oit the held-magnet back to terminal D, and thence by way of the successive resistancecoils between the terminal-blocks of are 8 to the controlling-lever 9 by way of contact-block 20, Fig. 4, thence by way of cable 73 to the contact-strip 32, Fig. 5, and from there back to the return-main. lt will be observed from the connections, Fig. l, through the solenoid at the right ol the lever i8 that if the lever should happen to bein the parallel 7 position at this time it will be thrown back tothe scries position. As the lever 9 is moved from left to right in either Fig. l or Fig. 5 it willbe observed that the resistances in the armature-Y circuit, which are located between the difterent blocks of the are 8, will be gradually cnt out. These resistancesarepreferablygreater between the blocks at the left et the are than at the right, and they can be so proportioned that the motor will barely turn when the controlling-lever i) is in the position shown in full lines in Fig. l. As the lever is moved to the right these resistances will be successively cut out and the armature will therefore rotate faster. As the controlling-lever 9 comes into contact with block D, Fig. l, it strikes a switch-lever 37 (see Fig. 3) and moves the same into contact with the terminal 3). This reduces the strength ol' the lield, preferably by short-eireuiting a part ot the series-field compounding, thus cutting out the ohmic resistanee of this winding and also cutting down the magnetic lines in the field and allowing the armature to rotate faster. As the controllinglever moves farther to the right the lever 37 contacts with both the terminals 3D an d and shortcircnits another part, which may be the rest, if desired, ofthe field compounding, thus further increasing the speed of the motor, and the amounts so short-circuited can be so pro-A portioned that no jerk from the increase of speed will result. As the controlling-lever moves tothe right more resistance will be cut out and the lever will strike the spring-contact 4l and merely push the same to one side, but will not close the circuit at this point. As the lever 9 moves oit from the terminal C, Fig. l, it contacts with the terminals 2S 29, closing the circuit through the solenoid at the left of the switch-lever 4S, drawing the core to the left and throwing the switch L1S over into the opposite pair ol' jaws. The armature-circuit will then be through the windAA ings in parallel, and instead of entering the line of contacts at A or C it will enter at E. In switching any armature windings from IOC IOS

IIO

series to parallel the resistance of the armature-circuit is reduced, and therefore in this case there would be a sudden rush of current through the windings, which would tend to drag the armatures quickly up to the new speed, and this would result in a quick jerk on the printing-press if some means for preventing` this were not provided. Any quick jerk in changing from one manner of connection to the other isa serious matter in the running of printing-presses, forin all probability the paper running through the press would be broken. Between the contact-block F and the block E where the current then enters is a series of resistances which in the aggregate are substantially sufficient to compensate for the decreased resistance through the windings in their parallel connection and is preferably just enough so that the armature will rotate slightly faster when the change is made from the series to the parallel connection; but the difference should not be so great as to make any jerk. As the lever 9 moves to the right some of this additional resistance is cut out, and the speed of rotation of the armature will therefore further increase. The contact-strip 30 is a part of the shunt field-circuit. This shunt fieldcircuit in the present embodiment remains the same until the controlling-lever 9 strikes the contact-block E. The segment 30 is there divided into several contact-blocks 3OfL 30", thc., which are insulated from each other, but are connected by a series of resistances. As the lever moves to the right over the contactblock E it will cut these resistances into the shunt eld-circuit in succession and weaken by so much the iield ofthe motors, and therefore further increase .the speed. 75 are spring-stops to limit the movement of the lever 9. The lever 9 is now at the end of its forward stroke and the hand-lever 12 is also at the end of its traverse in one direction. As the hand-lever12 moves in the reverse direction the controlling-lever will also move backward, and the resistance between the blocks 30a 30h, itc., will be successively cut out, thus increasing the strength of the eld and reducing the speed of rotation of the armatures, and as the hand-lever moves to the left, olf from the contact-block E and over the other blocks, resistances will be introduced in succession into the armature-circuit and will therefore further reduce the speed of the motor. When the controlling-lever 9 strikes the pin 40 on the movable contactpiece 41, it will push the piece 41 to the left (see Fig. 5) until it strikes the contact-piece 43. This will close the circuit through the righthand solenoid of the switch 4S and through the left-hand solenoid of the lever 47, Fig. 1, thus opening the armature-circuit and preferably throwing the windings back into series at the same time. As the controlling-lever moves farther to the left it will strike the switch-lever 37 and move the same off from contact with terminals 38 and 39.

When the lever reaches the position shown in Fig. 1 in full lines, it will close the circuit through the right-hand solenoid of the switch 47, thus closing the circuit through the armature-windings,which are again in series. The pressman may therefore, by motion of the hand-lever 12 in one direction, start his press at the slowest speed desired and steadily increase the speed without any jerk up to the full speed of the windings in parallel and by a movement of the hand-lever in the reverse direction reduce the speed until the windings are thrown from parallel back to series, when the entire current will be out off from the armature-circuit, and all the pressman has to do to reduce the speed gradually from this point is to quickly draw back the hand-lever to the position shown in Fig, 1 and then move it forward again until he meets the speed of the motor, which is of course beginning to run slower. If he desires to stop themotor, no matter in what position the lever is all he needs to do is to bring the controlling-lever 9 back to the position shown in Fig. 5 by moving the hand-lever to the end of its traverse, when the contacts 24 35 will be bridged and the switch 47 thrown into the open position. To stop the press suddenly-for instance, when there is not time to reach the hand-lever-we have provided a plurality of emergency-switches--such as 80, Fig. 1--located at different point-s around the press, which switches may he in the floor, as footswitches or otherwise, which will connect the righthand solenoid of switch 48 and the left-hand solenoid of switch 47, preferably in parallel, thus opening the armature-circuit and at the same time throwing the armature-windings back to the series connection.

Referring to the hand-switch 46 at the left of Fig. 1, it will be seen that the three contact-blades 45 45 45b will successively close the terminals which lead to them. In this way practically three successively-operating switches are provided by one movement. When the switch-'blade 45 touches its terminals, the armature-circuit is closed as far as switch 47, allowing the electromotive force from the entering-main to be im pressed. upon the lower terminal of the switch 47 and also upon the shunt field-circuit. On the further movement of the switch-lever 46 the blade 45a will close the other terminal of the shunt field-circuit, thus completing it, and when the switch 46 is thrown to its final closed position the blade 45b will close the path from the upper terminal of the switch 47 to the return-main. When the switch 46 is opened, the circuit through the field-shunt is opened and a return-current powerful enough to break down the insulation might result, and we therefore have short-circuited this eldshunt through a safety-resistance, which in IOO IIO

the present embodiment is represented in Fig. 1 by field choke-coils. In order to close this field shunt-circuit through this safetyresistance, preferably just before or substane assess tially at the same time as the circuit is broken by the switch itl, we have provided a pushswitch 77, Fig. l, which is engaged by the blade 45 of the switch 4G, so that when the switch 46 is closed the shunt-circuit through the choke-coils is opened; but just before or at the same time as that shunt field-circuit is opened by means of switch lltlaspring presses t-he push-contact 77 into engagement with suitable terminals which close the field shuntcircuit through this safety-resistance.

Then we speak of a han d-lever, we do not mean necessarily that it must be a straight lever, as shown in the present embodiment, because a hand-wheel or other analogous device might answer nearly as well and could, in fact, accomplish many of the advantages of the embodiment shown in the drawings. We are aware, further, that very many changes may be made in the construction herein disclosed without departing from the spiritof our invention, and we do not therefore desire to limit ourselves to the particular embodiment herein shown and described.

1. In combination, aplurality of armaturewindings, a hand-lever, means operated by the movement of said lever in one direction to connect said windings in series, a series of resistances in the armattire-circuit, means connected with said lever and adapted on the movement of said lever in one direction to cut out in succession some of said resistanees, a switch connected with said lever and operated by a further movement of said lever in the same direction to throw said windings into parallel and at the same time introduce into said circuit a series of substantially compensating resistances, and means connected with said lever and operated by a further movement of saidk lever in the same direction to cut out in succession some of said latter resistances.

2. In combination, a plurality of armaturewindings, means to connect the same in series, a hand-lever, a series of resistances in the armature-circuit, means connected with said lever and adapted on the movement of said lever in one direction to cut out in succession some of said resistances, means operated by the further movement ot' said lever in the same direction to reduce the strength of the lield, a switch connected with said lever and operated by a further movement of said lever iu the same direction to throw said windings into parallel and at the same time introduce into said circuit a series of substantially compensating resistances, and means connected with said lever and operated by a further.

movement of said lever in the same direction to eut out in succession some of said latter resistances.

3. In combination, a plurality et' armaturewindings, a series of resistances in the armature-circuit, means connected with said lever and adapted on the movement of said lever in one direction to out ont in succession some of said resistances, means operated by the further movement of said lever in the same direction to cut out some of the Vlield-coils to thereby reduce the strength of the Iield, a switchconnected with said leveran d operated by a further movement of said lever in the same direction to throw said windings into parallel and at the same time introduce into said circuit a series ol`; substantially compensating resistances, and means connected with said lever and operated by a further movement of said lever in the same direction to cut out in succession some of said latter resistances.

l-. In combination,acompound-wound lield magnet, a plurality of armature-windings, a hand-lever, a series of resistances in the armature-circuit, means connected with said lever and adapted on the movement of said lever in one direction to cut out in succession some of said resistances, means operated by the further movement of said lever in the same direction to eut out some of the series field-coils to thereby reduce the strength of the held, a switch connected with said lever and operated by a further movement of said lever in the sa me direction to throw said windings into parallel and at the same time introduce into said circuit a series ol substantially compensating resistances,and means connected with said lever and operated by the further movement of said lever in the same direction to cut out in succession some of said latter resistances.

5. In combinatioma com pound-wound (ieldmagnet, a plurality of armature-windings, a hand-lever, a series of resistances in the armature-circuit, means connected with said lever'and adapted on the movement of said lever in one direction to cutout in succession some of said resistanccs, means operated by the further movement of said lever in the same direction to cut out some of the series field-coils to thereby reduce the strength of the eld, a switch connected with said lever and operated by a further movement ot said lever in the same direction to throw said windings into parallel and at the same time introduce into said circuit a series of substantially compensating resistances, means connected with said lever and operated by the 'further movement ot said lever in the same direction to cut out in succession some of said latter resist-ances, and means also operated by the movement of said lever in the same direct-ion to introduce into the field-circuit in succession a series of resistances.

t5. In combination, a plurality of armaturewindings, means to connect the same in series, a series ot resistances in the armaturecircuit, contact-terminals for said resistances, connections, and a switch therefor, to throw said motors into parallel, a series of substantially compensating resistances, contact-terminals therefor, all ot' said terminals being arranged around a circle, a pivoted controlling-lever adapted to move around said circle IIO and provided with means to make electrical contact in succession with said terminals, means controlled'by said lever to throw said switch and at the same time introduce said compensating resistances into said armaturecircuit, and a hand-lever connected with said controlling-lever to move the same over said terminals by a movement of said hand-lever in one direction.

7. In combination, a plurality of armaturewindings, means to connect the same in series, a series of resistances in the armaturecircuit, contact-terminals forsaid resistances, connections, and a switch therefor, to throw said windings into parallel, a series of substantially compensating resistances, contactterminals therefor, all of said terminals being arranged around a circle, a pivoted controlling-lever adapted to move around said circle and provided with means to make electrical contact in succession with said terminals, means, controlled by said lever to throw said switch and at the same time introduce said compensating resistances into said armaturecircuit,includingapair of oppositely-disposed electromagnets, a circuit for each, and means to automatically close said magnet-circuits alternately, and a hand-lever connected with said controlling-lever to move the same over said terminals by a movement ot said handlever in one direction.

8. In combination, a plurality of armaturewindings, a hand-lever, means operated by a movement of said lever in one direction to connect said windings in parallel and at the same timeintroduce into the armature-circuit a series of substantially compensating resistances, and, by a further movement of said hand-lever in the same-direction, to cut said resistanees out in succession, means controlled bysaid lever and adapted, on the movement of said leverin the reverse direction, to introduce into said armature-circuit in succession some of said resistances, and means controlled by said hand-lever and operated by a further movement of the same in said reverse direction to throw said windings back from parallel into series.

9. In combination, a plurality of armaturewindings, a hand-lever, means operated by a movement of said lever in one direction to connect said windings in parallel and at the same timeintroduce into the armature-circuit a series of substantially compensating resistances, and, by a further movement of said hand-lever in the same direction, to eut said resistances out in succession, means controlled by said leverand adapted, on the movement of said lever in the reverse direction, to introduce into said armature-circuit in succession some of said resistances, and means controlled by said hand-lever and operated by a further movement of the same in said reverse direction to open said armature-circuit.

10. Incombination,apluralityofarmaturewindings, a hand-lever, means operated by a movement of said lever in one direction to connect said windings in parallel and at the same time introduce into the armature-circuit a series of substantially compensating resistances, and, by a further movement of said hand-lever in the same direction, to cut said resistances out in succession, means controlled by said lever and adapted, on the movement of said lever in the reverse direction, to introduce i'nto said armature-circuit in succession some of' said resistances, and means controlled by said hand-lever and operated by a further movement of the same in said reverse direction to open said armatu 11e-circuit, and at the same time throw said windings back from parallel into series. y ll. In combinatioman elcctroinagnet,means to energize the same, an armature for said magnet adapted to be moved by said magnet when the same is energized, an abutment moved by said armature, a movable switch-lever having a part connected with said armature adapted to move said lever and standingin the path of movement of said abutment, said abutment being normally separated from said part connected with said lever whereby said abutment strikes a quick ham mer-blow to throw said switch-lever when said magnet is energized. Y

l2. In combination, a solenoid, means to energize the same, acore forsaid solenoid adapted to be moved into the same when said solenoid is energized, an abutment on said core, a movable switch-lever having a part connected with said core adapted to move said lever and standing in the path of movement of said abutment, said abutment being nor- `mally separated from said part connected with said lever whereby said abutment strikes a quick hammer-blow to throw said switchlever when said solenoid is energized.

13. In combination, a solenoid, a core for said solenoid adapted to be moved into the same when said solenoid is energized, said,

core having a slot therein, a movable switchlever having a part connected therewith located in said slot, said part being adapted to move said lever and standing in the path of movement of the ends of said slot, one end of said slot being normally separated from said part connected with said lever whereby the end of said slot strikes a quick hammerblow to throw said switch-lever when said solenoid is energized. n

llt.A In combination, a solenoid, a core for said solenoid adapted to be moved into the same when said solenoid is energized, said core having a slot therein, a movable switchlever having a part connected therewith located in the slot, said part standing in the path of movement of the ends of said slot and adapted to move said lever, one end of said slot being normally separated from said part connected with said lever whereby said end of said slot strikes a quick hammer-blow to throw-said switch-lever when said solenoid is IOC IIO

IZO

energized, and an auxiliary core within said solenoid to increase the initial effect of the same upon said movable core.

15. In combination, a solenoid, a movable core located partly within and movable into said solenoid when the same is energized, and an auxiliary loosely-movable core also within said solenoid but normally separated Yfrom said movable core and operating` to increase the initial magnetic effect of said "solenoid on said movable core.

1G. In combination, a solenoid, a movable core located partly within and movable into said solenoid when the same is energized, an auxiliary movable core also within said soienoid but normally separated from said `lirst core, said auxiliary core being` moved toward said first core when said solenoid is energized and operating to increase the initial magnetic effect of said solenoid on said first core.

17. In combination, a solenoid, a movable core located partly within and movable into said solenoid when the same is energized, and an auxiliary movable core also within said solenoid but normally separated from said rst core and operating to increase the initial magnetic effect of said solenoid on said first core, said auxiliary core adapted to be moved by said lirst movable core.

18. In combination a pair of opposiiely-disposed solenoids, a movable core between said solenoids and adapted to enter the same alternately, a normally-open electric circuit through each solenoid, a contactbloei; to which the source of electricity is connected and a switch-lever in each of said solenoidcircuits adapted to alternately make connection with said contact-block, manually-controlled means to close said solenoid-circuits alternately, and means, Operated on the movement of said core, to automatically move the switch-lever in the closed solenoid-circuit out of connection with said contact-block, thereby breaking said closed solenoid-circuit, and move the other lever int-o connection with said contact-block while its solenoid-circuit remains open.

19. In combination, apairofoppositely-disposed solenoids, a movable core between said solenoids and adapted to enter the same alternately, a pair of elect-ric circuits, each circuit including as a part thereof one of said solenoids, each of said circuits being normally open, manually-operated means to close said circuits alternately, and means automatically operated on the movement of said core to open the circuit so closed.

20. 1n combination, a switch, a pair of oppositely-disposed solenoids, a movable core between said solenoids and adapted to enter the same alternately, a connection between said switch and core, a circuit through each solenoid, a pair of switches to automatically close said circuits through said solenoids alternately and thereby move said core and also throw said switch, and means operated bysaid core to automatically open the switch in the closed solenoid-circuit on the movement of said core and consisting ot` a lever connected with said core and adapted to contact with said solenoid-switches.

2l. In combination, a switch having a blade, a spring-jaw circuit-terminal engaged by said blade, a pair of oppositely-disposed solenoids, a movable core between said solenoids and adapted to enter the same alternately, a connection between said switch and core, a circuit through each solenoid, means to automatically close said circuits through said solenoids alternately and thereby move said core and throw said switch-blade out of said spring-jaw, and means to automatically open the closed solenoid-circuit during the movement of said core and after said blade leaves said terminal.

ln combination, a plurality of armature-windings on the same shaft,- a hand-lever, means operated by the movement of said lever in one direction to connect said windings in series, a series of resistances in the armature-circuit, means connected with said lever and adapted on the movement ot' said lever in one direction to cut out in succession some of said resistances, a switch connected with said lever and operated by a further movement of said lever in the same direction to throw said windings into parallel and at the same time introduce into said circuit a series of substantially compensating resistances, and means connected with said lever and operated by a further movement of said lever in the same direct-ion to cut outin succession some of said latter resistances.

23. 1ncombination,apluralityofarmaturewindings on the same shaft, means to connect the same in series, a hand-lever, a series of resistances in the armature-circuit, means connected with said lever and adapted on the movement of said lever in one direction to cut out in succession some of said resistances, means operated by the further movement of said lever in the same direction to reduce the strength of the field, a switch connected with said lever and operated by a further movenient of said lever in the same direction to throw said windings into parallel and at the same time introduce into said circuit a series of substantially compensating resistances, and means connected with said lever and operated by a further movement of said lever in the same direction to cut out in succession some of said latter resistances.

ln combination, a switch-bl ade having an aperture, a lever carrying the saine, a pin on said lever entering said aperture in said blade, insulation on said pin and between it and said blade, anda sleeve surrounding said pin and insulation and located between said insulation and blade to distribute the blow from said blade.

25. In combination, a switch-blade having an aperture, alever carrying the same, a pin on said lever entering said aperture in said blade, an insulated cushion on said pin and IOC IIO

between it and said blade and a sleeve surrounding said pin and cushion andy between said cushion and blade to distribute the blow from said blade, said blade being insulated from said lever.

26. In combination, a printing-press, a plurality of armature-windings, suitable circuits and a switch controlling the same to throw said windings from parallel to series connection, a second switch to open the armaturecircuit, an electromagnet to actuate each switch, a plurality of emergency-switches located at different points around said printing-press, and connections from the circuits through said electromagnets to the terminals of each ofl said emergency-switches to energize both of said magnets at the same time.

27. In combination, a printing-press, a plurality of armature-windin gs, suit-able circuits and a switch controlling the same to throw said windings from parallel to series connection, a second switch to open the armaturecircuit, an electromagnet to actuate each switch,a plurality of emergency push-switches located in the iioor at different points around said printing-press, and connections from the circuit-s through said electromagnets to the terminals of each of said emergency-switches to energize both of said magnets at the same time.

28. In combination, an electromotor, a switch to open a eld-circuit of said motor, a safety resistance, a/short circuit through said resistance for said field circuit, a springpressed switch adapted to be released and close said short circuit when said field-cire uit switch is opened.

29. In combination, an electromotor, a switch to open a field-circuit of said motor, a safety resistance, a short circuit through said resistance for said fieldcircuit, a springpressed switch resting against said first switch and adapted to be released and close said short circuit when said ield-circuit switch is opened.

30. In combinatioma plurality of armaturewindings, means to connect the same in series, a series of resistances in the armature-circuit, contact-terminals for said resistances, connections, and a switch therefor, to throw said motors into parallel, a series of substantially compensating resistances, contact-terminals therefor, all of said terminals being arranged in succession, an arm adapted to move over said terminals and provided with means to make electrical contact in succession with the same, means controlled by said arm to throw said switch and at the same time introduce said compensating resistances into said armature-circuit, and a hand-lever con- 6o nected with said controlling-arm to move the same over said terminals by a movement of said hand-lever lin one direction.

3l. In combination,a plurality of armaturewindings on the same shaft, a hand-lever, means operated by a movement of said lever in one direction to connect said windings in parallel and at the same time introduce into the armature-circuit a series of substantially compensating resistances, and, by a further movement of said hand-lever in the same direction, to cut said resistances out in succession, ymeans controlled by said lever and adapted, on the movement of said lever in the reverse direction, to introduce into said armature-circuit in succession some of said resistances, and means controlled by said hand-lever and operated by a further movement of the same in said reverse direction to throw said windings back from parallel into series.

32. In combinatioma plurality of armaturewindings on the same shaft, a hand-lever, means operated by a movement of said lever in one direction to connect said windings in parallel and at the same time introduce into the armature-circuit a series of substantially compensating resistances, and, by a further movement of said hand-lever in the same direction, to cut said resistances out in suc' oids, a part moved by said solenoids alternately and in opposite directions, a connection between said switch and said movable part, Aa normally-open circuit through each solenoid, means to automatically close said circuits through said solenoids alternately and thereby move said part and throw said switch, and means operated by the movement of said part to automatically open the closed solenoid-circuit without closing the other solenoid-circuit.

Signed at Westeld, New Jersey, this 29th day of March, 1900.

WILLIAM BREWS'IER ELLIOTT, JOHN WILLIAM ESKHOLME.

Witnesses:

C. H. FLORANDIZ, R. V. MARR.

IOC

IIO 

